Photodetection apparatus

ABSTRACT

A pixel section P m,n  includes a photodiode PD, a first capacitance section C 1 , a second capacitance section C 2 , and transistors T 1 -T 6 . The transistor T 1  transfers the electric charge generated by the photodiode PD to the first capacitance section C 1 . The transistor T 2  transfers the electric charge generated by the photodiode PD to the second capacitance section C 2 . The amplification transistor T 3  outputs a voltage value corresponding to the amount of electric charge accumulated in the first capacitance section C 1 . The transistor T 4  selectively outputs to the wiring L 1,n  the voltage value outputted from the amplification transistor T 3 . The transistors T 3  and T 4  constitute a source follower circuit. The transistors T 5  and T 6  selectively output to the wiring L 2,n  the electric charge accumulated in each of the first capacitance section C 1  and the second capacitance section C 2 .

RELATED APPLICATION

This is a continuation-in-part application of application serial no. PCT/JP2005/014910 filed on Aug. 15, 2005, now pending.

TECHNICAL FIELD

The present invention relates to a photodetection apparatus for converting light into an electric signal and then outputting the signal.

RELATED BACKGROUND ART

Photodetection apparatuses are known that employ the CMOS (Complementary Metal Oxide Semiconductor) technique. Among these, in particular, those employing an active pixel method are well known (see, for example, Patent Document 1). Such a photodetection apparatus of the active pixel method comprises an active pixel type pixel section including a photodiode for generating electric charge of an amount corresponding to incident light intensity, and thereby performs charge-voltage conversion on the electric charge generated by the photodiode in correspondence to the light incidence in the pixel section, via a source follower circuit composed of a transistor. This photodetection is achieved with high sensitivity and low noise.

When the charge accumulation capacitance value is denoted by C_(f) in a floating diffusion region for accumulating the electric charge generated by the photodiode in the pixel section, and when the amount of the electric charge is denoted by Q, the output voltage value V acquired by the charge-voltage conversion is expressed by a formula V=Q/C_(f). As seen from this formula, when the charge accumulation capacitance value C_(f) of the floating diffusion region is reduced, the sensitivity can be increased in the photodetection.

Patent Document 1: Japanese Patent Laid-Open publication No. Hei-11-274454

Nevertheless, the output voltage value V is restricted to a few V at maximum owing to the available range of the supply voltage and various limitations in the circuit system. Further, the amount Q of electric charge that can be accumulated in the floating diffusion region also has an upper limit. This also places a restriction on the output voltage value V.

In order to increase the upper limit (saturation electric charge amount) of the amount Q of electric charge which can be accumulated in the floating diffusion region, the charge accumulation capacitance value C_(f) of the floating diffusion region may be increased, or alternatively the supply voltage value may be increased. Nevertheless, the increasing of the capacitance value C_(f) of the floating diffusion region requires the reducing of the supply voltage value. As a result, no increased saturation electric charge amount is obtained. Further, when the charge accumulation capacitance value C_(f) of the floating diffusion region is increased, the remarkable advantage of high sensitivity is lost.

As such, a prior art photodetection apparatus can perform photodetection with high sensitivity, but has the disadvantage of a narrow dynamic range of the photodetection caused by the restriction in the saturation electric charge amount.

SUMMARY OF THE INVENTION

The invention has been devised in order to resolve the above-mentioned problem. An aspect of the invention is to provide a photodetection apparatus capable of performing photodetection with high sensitivity and a wide dynamic range.

It is one aspect of the present invention to provide a photodetection apparatus comprising: (1) a pixel section including a photodiode for generating electric charge of an amount corresponding to incident light intensity, a first capacitance section for accumulating the electric charge generated by the photodiode, a second capacitance section having a larger charge accumulation capacitance than the first capacitance section and thereby accumulating the electric charge generated by the photodiode, first transfer means and second transfer means for transferring the electric charge generated by the photodiode respectively to the corresponding first capacitance section and the second capacitance section, an amplification transistor a gate terminal of which is connected to the first capacitance section and which outputs a voltage value corresponding to the amount of electric charge accumulated in the first capacitance section, first output means for selectively outputting the voltage value outputted from the amplification transistor, second output means for selectively outputting the electric charge accumulated in each of the first capacitance section and the second capacitance section, and initializing means for initializing the electric charge of each of the first capacitance section and the second capacitance section; (2) a first signal processing section for reading the voltage value outputted by the first output means of the pixel section and thereby outputting a first voltage value corresponding to the voltage value; and (3) a second signal processing section for reading the electric charge amount outputted by the second output means of the pixel section and thereby outputting a second voltage value corresponding to the electric charge amount.

In this photodetection apparatus, in the pixel section, when the photodiode generates electric charge of an amount corresponding to incident light intensity, the electric charge is transferred by the first transfer means and then accumulated in the first capacitance section, or alternatively transferred by the second transfer means and then accumulated in the second capacitance section. A voltage value corresponding to the amount of electric charge accumulated in the first capacitance section is outputted from the amplification transistor. The voltage value is selectively outputted from the pixel section by the first output means. The electric charge accumulated in each of the first capacitance section and the second capacitance section is selectively outputted from the pixel section by the second output means. The voltage value outputted by the first output means of the pixel section is read by the first signal processing section, so that a first voltage value corresponding to the voltage value is outputted. Further, the electric charge amount outputted by the second output means of the pixel section is read by the second signal processing section, so that a second voltage value corresponding to the electric charge amount is outputted. The first voltage value expresses with high sensitivity the incident light intensity on the pixel section. On the other hand, the second voltage value expresses with a wide dynamic range the incident light intensity on the pixel section.

Preferably, in the photodetection apparatus according to the invention, (1) the pixel section further includes third output means for selectively outputting the electric charge generated by the photodiode via a route not passing through the first capacitance section and the second capacitance section, while (2) the apparatus further comprises a third signal processing section for reading the electric charge amount outputted by the third output means of the pixel section and thereby outputting a third voltage value corresponding to the electric charge amount. The second signal processing section may also serve as the third signal processing section. In this case, the electric charge generated by the photodiode of the pixel section is selectively outputted by the third output means via a route not passing through the first capacitance section and the second capacitance section. The amount of the electric charge is read by the third signal processing section so that a third voltage value corresponding to the electric charge amount is outputted. This third voltage value expresses the incident light intensity on the pixel section with a much wider dynamic range.

Preferably, the second signal processing section includes: (1) an amplifier which includes a first input terminal, a second input terminal, and an output terminal, and in which the first input terminal receives the electric charge amount outputted by the second output means of the pixel section while the second input terminal receives a reference voltage; and (2) a feedback capacitance section connected between the first input terminal and the output terminal of the amplifier, wherein the electric charge amount outputted by the second output means of the pixel section is accumulated in the feedback capacitance section, so that a second voltage value corresponding to the amount of accumulated charge is outputted. Further, preferably, the first input terminal of the amplifier of the second signal processing section is connected via a common terminal to the second output means and the initializing means of the pixel section, while the value of the reference voltage inputted to the second input terminal of the amplifier of the second signal processing section is variable. In this case, preferably, the capacitance value of the feedback capacitance section is variable.

Preferably, the photodetection apparatus according to the invention further comprises a selecting section for receiving the first voltage value outputted from the first signal processing section and the second voltage value outputted from the second signal processing section and thereby selecting and outputting any one of these voltage values consisting of the first voltage value and the second voltage value. Further, when the third signal processing section is provided, the photodetection apparatus according to the invention, preferably, further comprises a selecting section for receiving the first voltage value outputted from the first signal processing section, the second voltage value outputted from the second signal processing section, and the third voltage value outputted from the third signal processing section, and thereby selecting and outputting any one of these voltage values consisting of the first voltage value, the second voltage value, and the third voltage value. Preferably, the photodetection apparatus further comprises an A/D conversion section for receiving the voltage value outputted from the selecting section, thereby performing A/D conversion, and then outputting a digital value corresponding to the voltage value. Moreover, preferably, the photodetection apparatus further comprises a bit shift section for receiving the digital value outputted from the A/D conversion section, then shifting the bit of the digital value depending on which value has been selected in the selecting section, and then outputting the value.

The present invention will be more fully understood from the detailed description given hereinbelow and the accompanying drawings, which are given by way of illustration only and are not to be considered as limiting the present invention.

Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will be apparent to those skilled in the art from this detailed description.

The invention realizes photodetection with high sensitivity and a wide dynamic range.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic configuration diagram of a photodetection apparatus 1 according to an embodiment of the invention;

FIG. 2 is a configuration diagram of a photodetection section 10 of a photodetection apparatus 1 of FIG. 1;

FIG. 3 is a circuit diagram of a pixel section P_(m,n) included in a photodetection section 10 of FIG. 2;

FIG. 4 is a sectional view of a photodiode PD included in a pixel section P_(m,n);

FIG. 5 is a configuration diagram of a first signal processing section 20 of a photodetection apparatus 1 of FIG. 1;

FIG. 6 is a circuit diagram of a voltage hold section H_(n) included in a first signal processing section 20 of FIG. 5;

FIG. 7 is a configuration diagram of a second signal processing section 30 of a photodetection apparatus 1 of FIG. 1;

FIG. 8 is a circuit diagram of an integration circuit 31 _(n), a CDS circuit 32 _(n), and a hold circuit 33 _(n) included in a second signal processing section 30 of FIG. 7;

FIG. 9 is a configuration diagram of a data output section 40 of a photodetection apparatus 1 of FIG. 1; and

FIG. 10 is a timing chart describing an example of operation of a photodetection apparatus 1 of FIG. 1.

BEST MODES FOR CARRYING OUT THE INVENTION

The best mode for carrying out the invention is described below in detail with reference to the accompanying drawings. In the following description of the drawings, like components are designated by like numerals so that overlapping description is omitted. Further, M and N indicate integers greater than or equal to 2, while m indicates an arbitrary integer ranging from 1 to M inclusive, and while n indicates an arbitrary integer ranging from 1 to N inclusive.

FIG. 1 is a schematic configuration diagram of a photodetection apparatus 1 serving as an embodiment of the invention. FIG. 2 is a configuration diagram of a photodetection section 10 of this photodetection apparatus 1. The photodetection apparatus 1 shown in these figures comprises a photodetection section 10, a first signal processing section 20, a second signal processing section 30, a data output section 40, and a timing control section 50. These components are preferably formed on a common semiconductor substrate. In this case, the arrangement on the substrate is preferably as shown in the figure. Here, the timing control section 50 for controlling the operation of the entire photodetection apparatus 1 may be divided into sub-sections and arranged at mutually distant positions on the substrate.

The photodetection section 10 comprises M×N pixel sections P_(m,n) arranged in two dimensions of M rows and N columns. Each pixel section P_(m,n) is located at m-th row and n-th column. Each pixel section P_(m,n) has a common configuration including a photodiode and the like. Then, each pixel section P_(m,n) outputs to a wiring L_(1,n) a voltage value corresponding to the intensity of light made incident on the photodiode, and outputs to a wiring L_(2,n) the electric charge of the amount corresponding to the light intensity. Each wiring L_(1,n) is connected in common to the output terminal of each of the M pixel sections P_(1,n)-P_(M,n) in the n-th column. Further, each wiring L_(2,n) is connected in common to another terminal of each of the M pixel sections P_(1,n)-P_(M,n) the n-th column.

The first signal processing section 20 is connected to the N wirings L_(1,1)-L_(1,N), thereby receives the voltage value outputted from each pixel section P_(m,n) to the wiring L_(1,n), and then, after performing predetermined processing, outputs sequentially a first voltage value V_(1,m,n) indicating the pixel data. Each voltage value V_(1,m,n) has a value corresponding to the intensity of light made incident on the pixel section P_(m,n). In particular, this first voltage value V_(1,m,n) expresses with high precision the result of high sensitivity detection of the incident light intensity of the case when the capacitance section of the pixel section P_(m,n) is not saturated, that is, of the case when the intensity of the light made incident on the pixel section P_(m,n) is comparatively low.

The second signal processing section 30 is connected to the N wirings L_(2,1)-L_(2,N), thereby receives the electric charge outputted from each pixel section P_(m,n) to the wiring L_(2,n) then accumulates the electric charge in the capacitance section, and then outputs sequentially a second voltage value V_(2,m,n) corresponding to the amount of the electric charge accumulated in the capacitance section. The capacitance value of the capacitance section included in the second signal processing section 30 is greater than the capacitance value of the capacitance section included in the pixel section P_(m,n). Each voltage value V_(2,m,n) has a value corresponding to the intensity of light made incident on the pixel section P_(m,n). Further, the second voltage value V_(2,m,n) expresses with high precision the result of detection of incident light intensity even in the case that the capacitance section of the pixel section P_(m,n) is saturated, that is, even in the case that the incident light intensity on the pixel section P_(m,n) is comparatively high.

The data output section 40 receives the first voltage value V_(1,m,n) outputted from the first signal processing section 20 and the second voltage value V_(2,m,n) outputted from the second signal processing section 30, then performs predetermined processing, and thereby outputs a digital value D_(m,n). Each digital value D_(m,n) is a value of the result of A/D conversion of either the first voltage value V_(1,m,n) or the second voltage value V_(2,m,n), and indicates the intensity of light made incident on the pixel section P_(m,n).

The timing control section 50 controls the operation of the photodetection section 10, the first signal processing section 20, the second signal processing section 30, and the data output section 40. The timing control section 50 generates various kinds of control signals at predetermined timings by means of a shift register circuit or the like, and then transmits these control signals to the photodetection section 10, the first signal processing section 20, the second signal processing section 30, and the data output section 40. In FIGS. 1 and 2, it should be noted that a part of wiring for transmitting the control signals is omitted.

FIG. 3 is a circuit diagram of a pixel section P_(m,n) included in the photodetection section 10 of the photodetection apparatus 1. Each pixel section P_(m,n) includes a photodiode PD, a first capacitance section C₁, a second capacitance section C₂, and transistors T₂-T₆. The photodiode PD generates electric charge of an amount corresponding to the incident light intensity. Its anode terminal is maintained at the ground potential. In each of the first capacitance section C₁ and the second capacitance section C₂, a first terminal is grounded, while the electric charge generated by the photodiode PD is accumulated. The capacitance value of the second capacitance section C₂ is greater than the capacitance value of the first capacitance section C₁, preferably by a factor of ten or greater.

The transistor T₁ is arranged between the cathode terminal of the photodiode PD and the second terminal of the first capacitance section C₁. When a Trans1 signal inputted to the gate terminal is at a high level, the resistance between the source terminal and the drain terminal goes low so that the transistor T₁ serves as first transfer means for transferring the electric charge generated by the photodiode PD to the first capacitance section C₁. Further, the transistor T₂ is arranged between the cathode terminal of the photodiode PD and the second terminal of the second capacitance section C₂. When a Trans2 signal inputted to the gate terminal is at a high level, the resistance between the source terminal and the drain terminal goes low so that the transistor T₂ serves as second transfer means for transferring the electric charge generated by the photodiode PD to the second capacitance section C₂.

In the amplification transistor T₃, the gate terminal is connected to the first capacitance section C₁, so that a voltage value is outputted that corresponds to the amount of the electric charge accumulated in the first capacitance section C₁. Here, the first capacitance section C₁ may be a parasitic capacitance section formed in the gate terminal of the amplification transistor T₃, or alternatively may be a capacitance section fabricated intentionally. The transistor T₄ is provided between the amplification transistor T₃ and the wiring L_(1,n). When a Select signal inputted to the gate terminal is at a high level, the resistance between the source terminal and the drain terminal goes low so that the transistor T₄ serves as first output means for selectively outputting to the wiring L_(1,n) the voltage value outputted from the amplification transistor T₃. A constant current source is connected to the wiring L_(1,n). The transistors T₃ and T₄ constitute a source follower circuit.

The transistor T₅ is arranged between the first capacitance section C₁ and the wiring L_(2,n). When a Reset signal inputted to the gate terminal is at a high level, the resistance between the source terminal and the drain terminal goes low. Further, the transistor T₆ is arranged between the first capacitance section C₁ and the second capacitance section C₂. When a Com signal inputted to the gate terminal is at a high level, the resistance between the source terminal and the drain terminal goes low. These transistors T₅ and T₆ serve as second output means for selectively outputting to the wiring L_(2,n) the electric charge accumulated in each of the first capacitance section C₁ and the second capacitance section C₂, and also serve as initializing means for initializing the electric charge of each of the first capacitance section C₁ and the second capacitance section C₂. The second output means and the initializing means described here are connected to the second signal processing section 30 via a common terminal.

In each pixel section P_(m,n) having the above-mentioned configuration, in the case that the Trans1 signal is at a low level and that the Reset signal and the Com signal are at a high level, when a bias potential is inputted from the wiring L_(2,n) to the transistor T₅, the electric charge of each of the first capacitance section C₁ and the second capacitance section C₂ is initialized. When the Select signal is at a high level, a voltage value (dark signal component) corresponding to the initialization state is outputted from the amplification transistor T₃ via the transistor T₄ to the wiring L_(1,n).

On the other hand, in the case that the Reset signal is at a low level and that the Trans1 signal is at a high level, the electric charge generated by the photodiode PD is accumulated in the first capacitance section C₁. Further, in the case that the Reset signal is at a low level and that the Trans2 signal is at a high level, the electric charge generated by the photodiode PD is accumulated in the second capacitance section C₂. Then, when the Select signal is at a high level, a voltage value corresponding to the amount of the accumulated charge in the first capacitance section C₁ (bright signal component) is outputted from the amplification transistor T₃ via the transistor T₄ to the wiring L_(1,n). Further, when the Reset signal and the Com signal go to a high level, the electric charge accumulated in the first capacitance section C₁ is outputted to the wiring L_(2,n) via the transistor T₅, while the electric charge accumulated in the second capacitance section C₂ is outputted to the wiring L_(2,n) via the transistors T₅ and T₆.

Here, the Trans1 signal, the Trans2 signal, the Select signal, the Reset signal, and the Com signal are outputted from the timing control section 50.

FIG. 4 is a sectional view of a photodiode PD included in the pixel section P_(m,n). A buried type is preferable for the photodiode PD as shown in the figure. The photodiode PD includes: a p region 101; an n⁻ region 102 on the p region 101; and a p⁺ region 103 on the n⁻ region 102. The p region 101 and the n⁻ region 102 form a pn junction, while the n⁻ region 102 and the p⁺ region 103 also form a pn junction. Further, a part of the n⁻ region 102 reaches the surface of the semiconductor layer.

The transistor T₁ is formed by: an n region 104 on the p region 101; the above-mentioned part of the n⁻ region 102 that reaches the surface of the semiconductor layer; and a gate electrode 106 formed between these regions on an insulating layer 105. The n region 104 is electrically connected to the gate terminal of the amplification transistor T₃, and electrically connected to the source terminal of the transistor T₅. The p region 101 and the n region 104 form a pn junction, and constitute the first capacitance section C₁ for accumulating the electric charge generated by the photodiode PD in the pixel section P_(m,n).

When the photodiode PD is of a buried type as described here, the occurrence of a leakage current is suppressed in the surface. Further, when the reverse bias voltage of the photodiode PD is increased in the duration that the electric charge generated by the photodiode PD is transferred to the first capacitance section C₁, the depletion layer in the pn junction section of the photodiode PD can become complete so that the junction capacitance value of the photodiode PD can become almost zero. Thus, the electric charge generated by the photodiode PD can almost completely be transferred to the first capacitance section C₁. Accordingly, the use of a buried type photodiode PD is effective in the improving of the S/N ratio and the sensitivity in the photodetection.

FIG. 5 is a configuration diagram of a first signal processing section 20 of the photodetection apparatus 1 according to the present embodiment. The first signal processing section 20 includes N voltage hold sections H₁-H_(N), two voltage follower circuits F₁ and F₂, and a subtraction circuit S. Each voltage hold section H_(n) has a common configuration, and is connected to the wiring L_(1,n). Then, each voltage hold section H_(n) receives the voltage value outputted to the wiring L_(1,n) from each of the M pixel sections P_(1,n)-P_(M,n) in the n-th column, thereby can hold the voltage value, and can output the held voltage value. Each of the N voltage hold sections H₁-H_(N) outputs the voltage value sequentially. The voltage values held and outputted by each voltage hold section H_(n) are two voltage values V_(n,1) and V_(n,2) each outputted from the pixel section P_(m,n) at a mutually distinct time.

Each of the two voltage follower circuits F₁ and F₂ has a common configuration. That is, the inverting input terminal and the output terminal of the amplifier are connected directly to each other, while each voltage follower circuit has a high input impedance and a low output impedance and is ideally composed of a unity gain amplifier. In the one voltage follower circuit F₁, one voltage value V_(n,1) sequentially outputted from each of the N voltage hold sections H₁-H_(N) is inputted to the non-inverting input terminal. In the other voltage follower circuit F₂, the other voltage value V_(n,2) sequentially outputted from each of the N voltage hold sections H₁-H_(N) is inputted to the non-inverting input terminal.

The subtraction circuit S includes an amplifier and four resistors R₁-R₄. The inverting input terminal of the amplifier is connected to the output terminal of the voltage follower circuit F₂ via the resistor R₁, and then connected to the own output terminal via the resistor R₃. The non-inverting input terminal of the amplifier is connected to the output terminal of the voltage follower circuit F₂ via the resistor R₂, and then connected to the ground potential via the resistor R₄. When each of the voltage follower circuits F₁ and F₂ has a unity gain while the four resistors R₁-R₄ have the same resistance value with each other, the first voltage value V_(1,m,n) outputted from the output terminal of the subtraction circuit S is expressed by the formula V _(1,m,n) =V _(n,2) −V _(n,1).

FIG. 6 is a circuit diagram of a voltage hold section H_(n) included in the first signal processing section 20 of the photodetection apparatus 1. Each voltage hold section H_(n) includes a first hold section H_(n,1) and a second hold section H_(n,2). The first hold section H_(n,1) and the second hold section H_(n,2) have the same configuration as each other. Each hold section receives the voltage value sequentially outputted from the transistor T₄ of each of the M pixel sections P_(1,n)-P_(M,n) in the n-th column, and can thereby hold the voltage value, and output the held voltage value.

The first hold section H_(n,1) includes a transistor T₁₁, a transistor T₁₂, and a capacitance element C₁₀. One end of the capacitance element C₁₀ is maintained at the ground potential, while the other end of the capacitance element C₁₀ is connected to the drain terminal of the transistor T₁₁, and the source terminal of the transistor T₁₂. The source terminal of the transistor T₁₁, is connected to the transistor T₄ of the pixel section P_(m,n) via the wiring n. The drain terminal of the transistor T₁₂ is connected to the voltage follower circuit F₁. In the first hold section H_(n,1) having the configuration described here, when the Hold1 signal inputted to the gate terminal of the transistor T₁₁ is at a high level, the voltage value outputted from the pixel section P_(m,n) connected via the wiring L_(1,n) is held by the capacitance element C₁₀. Then, when the Output signal inputted to the gate terminal of the transistor T₁₂ is at a high level, the voltage value V_(n,1) held by the capacitance element C₁₀ is outputted to the voltage follower circuit F₁.

The second hold section H_(n,2) includes a transistor T₂₁, a transistor T₂₂, and a capacitance element C₂₀. One end of the capacitance element C₂₀ is maintained at the ground potential, while the other end of the capacitance element C₂₀ is connected to the drain terminal of the transistor T₂₁ and the source terminal of the transistor T₂₂. The source terminal of the transistor T₂₁ is connected to the transistor T₄ of the pixel section P_(m,n) via the wiring L_(1,n). The drain terminal of the transistor T₂₂ is connected to the voltage follower circuit F₂. In the second hold section H_(n,2) having the configuration described here, when the Hold2 signal inputted to the gate terminal of the transistor T₂₁ is at a high level, the voltage value outputted from the pixel section P_(m,n) connected via the wiring L_(1,n) is held by the capacitance element C₂₀. Then, when the Output signal inputted to the gate terminal of the transistor T₂₂ is at a high level, the voltage value V_(n,2) held by the capacitance element C₂₀ is outputted to the voltage follower circuit F₂.

Each of the first hold section H_(n,1) and the second hold section H_(n,2) operates in a distinct timing with each other. For example, in the pixel section P_(m,n) connected via the wiring L_(1,n) in the case when the Trans1 signal is at a low level and that the Reset signal and the Select signal are at a high level, the first hold section H_(n,1) holds the received voltage value (dark signal component) V_(n,1) outputted from the amplification transistor T₃. On the other hand, in the pixel section P_(m,n) connected via the wiring L_(1,n) in the case when the Reset signal is at a low level and that the Trans1 signal and the Select signal are at a high level, the second hold section H_(n,2) holds the received voltage value (bright signal component) V_(n,2) outputted from the amplification transistor T₃. Here, the Hold1 signal, the Hold2 signal, and the Output signal are outputted from the timing control section 50.

FIG. 7 is a configuration diagram of a second signal processing section 30 of the photodetection apparatus 1. The second signal processing section 30 includes N integration circuits 31 ₁-31 _(N), N CDS (Correlated Double Sampling) circuits 32 ₁-32 _(N), and N hold circuits 33 ₁-33 _(N). The integration circuits 31 _(n) have a common configuration, and are connected to the wiring L_(2,n). Then, each integration circuit 31 _(n) receives the electric charge outputted from each of the M pixel sections P_(1,n)-P_(M,n) in the n-th column to the wiring L_(2,n), thereby accumulates the electric charge, and then outputs a voltage value corresponding to the amount of the accumulated charge. The CDS circuits 32 _(n) have a common configuration. Then, each CDS circuit 32 _(n) receives the voltage value outputted from the integration circuit 31 _(n), and thereby outputs a voltage value corresponding to the difference in the input voltage values at a specific time and another time. The hold circuits 33 _(n) have a common configuration. Then, each hold circuit 33 _(n) receives the voltage value outputted from the CDS circuit 32 _(n), thereby holds the voltage value, and then outputs the held voltage value V_(2,m,n).

FIG. 8 is a circuit diagram of an integration circuit 31 _(n), a CDS circuit 32 _(n), and a hold circuit 33 _(n) included in the second signal processing section 30.

Each integration circuit 31 _(n) includes an amplifier A₃₁, capacitance elements C₃₁₁-C₃₁₃, and switches SW₃₁₀-SW₃₁₄. Either a reference voltage V_(ref1) or a reference voltage V_(ref2) is applied to the non-inverting input terminal of the amplifier A₃₁ via the switch SW₃₁₄. The reference voltage V_(ref2) is higher than the reference voltage V_(ref1). For example, the reference voltage V_(ref1) is approximately 1.5V, while the reference voltage V_(ref2) is approximately 3V. The inverting input terminal of the amplifier A₃₁ is connected to the wiring L_(2,n), and thereby receives the electric charge outputted from each of the M pixel sections P_(1,n)-P_(M,n) in the n-th column to the wiring L_(2,n).

Between the inverting input terminal and the output terminal of the amplifier A₃₁, arranged in parallel to each other are: the switch SW₃₁₀; the capacitance element C₃₁₁, and the switch SW₃₁₁ interconnected in series; the capacitance element C₃₁₂ and the switch SW₃₁₂ interconnected in series; and the capacitance element C₃₁₃ and the switch SW₃₁₃ interconnected in series. The capacitance elements C₃₁₁-C₃₁₃ and the switches SW₃₁₁-SW₃₁₃ constitute a feedback capacitance section having a variable capacitance value. That is, the feedback capacitance section constructed from these components is connected between the inverting input terminal and the output terminal of the amplifier A₃₁, and has a distinct capacitance value depending on the open/close states of the switches SW₃₁₁-SW₃₁₃.

The capacitance value of each of the capacitance elements C₃₁₁-C₃₁₃ is greater than the capacitance value of the first capacitance section C₁ included in the pixel section P_(m,n). The maximum capacitance value of the feedback capacitance section is in the order of or greater than the sum of the capacitance values of the first capacitance section C₁ and the second capacitance section C₂ included in the pixel section P_(m,n). Although the maximum capacitance value of the feedback capacitance section depends also on the mode of switching operation of each of the switches SW₃₁₁-SW₃₁₃, when the switches SW₃₁₁-SW₃₁₃ are closed simultaneously, the maximum capacitance value of the feedback capacitance section is the total of the capacitance values of the capacitance elements C₃₁₁-C₃₁₃. When any one of the switches SW₃₁₁-SW₃₁₃ is solely closed, the maximum capacitance value of the feedback capacitance section equals the maximum capacitance value among the capacitance elements C₃₁₁-C₃₁₃.

In the integration circuit 31 _(n), in the case that the switches SW₃₁₁-SW₃₁₃ are closed, when the switch SW₃₁₀ is also closed, the capacitance elements C₃₁₁-C₃₁₃ are discharged so that the voltage value outputted from the output terminal of the amplifier A₃₁ is initialized. When the switch SW₃₁₀ is open, the electric charge inputted through the wiring L_(2,n) is accumulated in the feedback capacitance section, so that a voltage value corresponding to the amount of the accumulated charge and the capacitance value of the feedback capacitance section is outputted from the output terminal of the amplifier A₃₁.

Each CDS circuit 32 _(n) includes an amplifier A₃₂, a capacitance element C₃₂, and switches SW₃₂₁, and SW₃₂₂. One end of the capacitance element C₃₂ is connected via the switch SW₃₂₁ to the output terminal of the amplifier A₃₁ of the integration circuit 31 _(n). The other end of the capacitance element C₃₂ is connected to the input terminal of the amplifier A₃₂, and connected to the ground potential via the switch SW₃₂₂. In this CDS circuit 32 _(n), at a first time, the switch SW₃₂₂ goes from the closed state to the open state. After that, at a second time, the switch SW₃₂₁ goes from the closed state to the open state. By virtue of this, a voltage value corresponding to the difference in the voltage values outputted from the integration circuit 31 _(n) at the first time and the second time is outputted from the output terminal of the amplifier A₃₂.

Each hold circuit 33 _(n) includes a capacitance element C₃₃ and switches SW₃₃₁ and SW₃₃₂. One end of the switch SW₃₃₁ is connected to the output terminal of the amplifier A₃₂ of the CDS circuit 32 _(n). One end of the switch SW₃₃₂ is connected to the output terminal of the hold circuit 33 _(n). The other end of the switch SW₃₃₁ and the other end of the switch SW₃₃₂ are connected to each other. This junction point is connected to the ground potential via the capacitance element C₃₃. In this hold circuit 33 _(n), when the switch SW₃₃₁ is closed, the voltage value outputted from the CDS circuit 32 _(n) is held by the capacitance element C₃₃. Then, when the switch SW₃₃₂ is closed, the voltage value held by the capacitance element C₃₃ is outputted as the second voltage value V_(2,m,n).

The switches SW₃₁₀-SW₃₁₄ of each integration circuit 31 _(n), the switches SW₃₂₁ and SW₃₂₂ of each CDS circuit 32 _(n), and the switches SW₃₃₁ and SW₃₃₂ of each hold circuit 33 _(n) perform open/close operation on the basis of the control signals outputted from the timing control section 50.

FIG. 9 is a configuration diagram of a data output section 40 of the photodetection apparatus 1. The data output section 40 includes a selecting section 41, an A/D conversion section 42, and a bit shift section 43.

The selecting section 41 receives the first voltage value V_(1,m,n) outputted from the first signal processing section 20 and the second voltage value V_(2,m,n), outputted from the second signal processing section 30, and then on the basis of the result of comparison of the first voltage value V_(1,m,n) with a reference value, selects and outputs any one of the voltage values consisting of the first voltage value V_(1,m,n) and the second voltage value V_(2,m,n).

Specifically, the reference value is set to be the saturation value of the first voltage value outputted from the first signal processing section 20, or alternatively to be a value slightly smaller than this value. That is, when the first voltage value V_(1,m,n) is compared with the reference value, it is determined whether the first capacitance section C₁ of the pixel section P_(m,n) is saturated. Then, when the first voltage value V_(1,m,n) is smaller than the reference value, the selecting section 41 outputs the first voltage value V_(1,m,n). On the contrary, when the first voltage value V_(1,m,n) is greater than or equal to the reference value, the selecting section 41 outputs the second voltage value V_(2,m,n).

Here, in place of the comparison of the first voltage value V_(1,m,n) with the reference value, the second voltage value V_(2,m,n) may be compared with the reference value. Also in this case, the reference value is set to be a value that permits the determination as to whether the first capacitance section C₁ of the pixel section P_(m,n) is saturated.

The A/D conversion section 42 receives the voltage value outputted from the selecting section 41, then performs A/D conversion on this signal, and then outputs a digital value corresponding to the voltage value.

The bit shift section 43 receives the digital value outputted from the A/D conversion section 42, and then shifts the bit of the inputted digital value by a necessary number of bits depending on which value has been selected from the first voltage value V_(1,m,n) and the second voltage value V_(2,m,n) in the selecting section 41. Then, the bit shift section 43 outputs the value. Specifically, in the case that the capacitance value of the feedback capacitance section of each integration circuit 31 _(n) is assumed to be 2^(K) times (K is an integer greater than or equal to 1) the capacitance value of the first capacitance section C₁ included in the pixel section P_(m,n), when the first voltage value V_(1,m,n) is selected in the selecting section 41, the bit shift section 43 outputs the inputted digital value intact as an output digital value D_(m,n). In contrast, when the second voltage value V_(2,m,n) is selected in the selecting section 41, the bit shift section 43 outputs as an output digital value D_(m,n) a value generated by shifting the inputted digital value upward by K bits. The output digital value D_(m,n) may be parallel data, or alternatively may be serial data.

As such, when the first capacitance section C₁ of the pixel section P_(m,n) is not saturated, that is, when the intensity of the light made incident on the pixel section P_(m,n) is comparatively low, a voltage value corresponding to the amount of the accumulated charge in the first capacitance section C₁ of the pixel section P_(m,n) is outputted to the wiring L_(1,n) by the first output means (transistor T₄), so that the first voltage value V_(1,m,n) corresponding to the voltage value is outputted from the first signal processing section 20. Then, the A/D conversion result of the first voltage value V_(1,m,n) is outputted as the digital value D_(m,n) from the data output section 40. This permits photodetection with high sensitivity.

In contrast, when the first capacitance section C₁ of the pixel section P_(m,n) is saturated (or almost saturated), that is, when the intensity of the light made incident on the pixel section P_(m,n) is comparatively high, the electric charge accumulated temporarily in the first capacitance section C₁ and the second capacitance section C₂ of the pixel section P_(m,n) is outputted to the wiring L_(2,n) by the second output means (transistors T₅ and T₆), so that the second voltage value V_(2,m,n) corresponding to the electric charge amount is outputted from the second signal processing section 30. Then, the A/D conversion result of the second voltage value V_(2,m,n) is outputted as the digital value D_(m,n) from the data output section 40. This permits photodetection with a wide dynamic range.

Thus, the photodetection apparatus 1 according to the present embodiment can perform image pick-up with high sensitivity and a wide dynamic range.

Moreover, in the photodetection apparatus 1, each pixel section P_(m,n) further includes third output means for selectively outputting the electric charge generated by the photodiode PD via a route not passing through the first capacitance section C₁ and the second capacitance section C₂. Furthermore, a third signal processing section is further provided that reads the electric charge amount outputted by the third output means of each pixel section P_(m,n) and thereby outputs a third voltage value V_(3,m,n) corresponding to the electric charge amount. Here, the third signal processing section may be provided separately from the second signal processing section 30. However, the third signal processing section may have a configuration similar to that of the second signal processing section 30. Thus, the second signal processing section 30 may also serve as the third signal processing section. However, when the second signal processing section 30 also serves as the third signal processing section, the second signal processing section 30 includes another hold circuit for holding and outputting the third voltage value V_(3,m,n) in addition to the hold circuit 33 _(n) for holding and outputting the second voltage value V_(2,m,n).

Further, when the third output means and the third signal processing section are provided, the selecting section 41 of the data output section 40 receives the first voltage value V_(1,m,n) outputted from the first signal processing section 20, the second voltage value V_(2,m,n) outputted from the second signal processing section 30, and the third voltage value V_(3,m,n) outputted from the third signal processing section (second signal processing section 30 in the case of shared configuration), and then selects and outputs any one of these voltage values consisting of the first voltage value V_(1,m,n), the second voltage value V_(2,m,n), and the third voltage value V_(3,m,n). After that, the bit shift section 43 receives the digital value outputted from the A/D conversion section 42, and then shifts the bit of the inputted digital value by a necessary number of bits depending on which value has been selected from the first voltage value V_(1,m,n), the second voltage value V_(2,m,n), and the third voltage value V_(3,m,n) in the selecting section 41. Then, the bit shift section 43 outputs the value.

When the third voltage value V_(3,m,n) is selected in the selecting section 41, a digital value D_(m,n) indicating the incident light intensity is outputted from the data output section 40 even when the intensity of the light made incident on the pixel section P_(m,n) is still greater than the case when the second voltage value V_(2,m,n) is selected. This permits photodetection with a much wider dynamic range.

Next, an example of operation of the photodetection apparatus 1 is described below. FIG. 10 is a timing chart describing an example of operation of the photodetection apparatus 1. The operation of the photodetection apparatus 1 described below is performed under the control of various kinds of control signals outputted from the timing control section 50.

This figure shows the time-dependent change of the levels of: the Reset signal inputted to the gate terminal of the transistor T₅ of each pixel section P_(m,n); the Trans1 signal inputted to the gate terminal of the transistor T₁ of each pixel section P_(m,n); the Trans2 signal inputted to the gate terminal of the transistor T₂ of each pixel section P_(m,n); the Com signal inputted to the gate terminal of the transistor T₆ of each pixel section P_(m,n); the Select signal inputted to the gate terminal of the transistor T₄ of each pixel section P_(m,n); the Hold1 signal inputted to the gate terminal of the transistor T₁₁ of each voltage hold section H_(n); and the Hold2 signal inputted to the gate terminal of the transistor T₂₁ of each voltage hold section H_(n); in descending order. Further, this figure shows the operation of the N pixel sections P_(m,1)-P_(m,N) of the m-th row among the M×N pixel sections P_(m,n) included in the photodetection section 10.

Before time t₁, the Reset signal, the Trans1 signal, the Trans2 signal, the Com signal, the Select signal, the Hold1 signal, and the Hold2 signal are at a low level. At time t₁, the Reset signal, the Trans1 signal, the Trans2 signal, the Com signal, and the Select signal go to a high level. Further, in the integration circuit 31 _(n), the reference voltage V_(ref2) (for example, 3V) is inputted to the non-inverting input terminal of the amplifier A₃₁ as a result of the operation of the switch SW₃₁₄. As a result, the first capacitance section C₁ and the second capacitance section C₂ of each pixel section P_(m,n) are discharged. After that, at time t₂, the Reset signal goes to a low level. Further, before time t₂, the Trans2 signal and the Com signal go to a low level.

Immediately after time t₂, the Hold1 signal temporarily goes to a high level, while at time t₃, the Hold1 signal goes to a low level. After time t₃, the Hold2 signal temporarily goes to a high level, while at time t₄ where a predetermined time has elapsed from time t₂, the Hold2 signal goes to a low level. Further, at time t₄, the Select signal goes to a low level. As a result, the voltage value (dark signal component) V_(n,1), outputted from the transistor T₄ of each pixel section P_(m,n) to the wiring L_(1,n) at time t₃ is held after the time t₃ by the capacitance element C₁₁ of the first hold section H_(n,1) of the voltage hold section H_(n). Further, in each pixel section P_(m,n), the electric charge generated by the photodiode PD in a predetermined duration from time t₂ to time t₄ is accumulated in the first capacitance section C₁. Then, the voltage value (bright signal component) V_(n,2) outputted from the transistor T₄ of each pixel section P_(m,n) to the wiring L_(1,n) at time t₄ is held after the time t₄ by the capacitance element C₂₀ of the second hold section H_(n,2) of the voltage hold section H_(n). After that, when the Output signal inputted to each of the N voltage hold sections H₁-H_(N) goes to a high level sequentially, the first voltage value V_(1,m,n) (=V_(n,2)−V_(n,1)) of each of the N pixel sections P_(m,1)-P_(m,N) of the m-th row is sequentially outputted from the first signal processing section 20.

At time t₅ after time t₄, the Trans2 signal goes to a high level, while at time t₆ after that, the Trans2 signal goes to a low level. As a result, in each pixel section P_(m,n), the electric charge generated by the photodiode PD in the duration from time t₂ to time t₆ is accumulated in both of the first capacitance section C₁ and the second capacitance section C₂.

At time t₇ after time t₆, the Reset signal and the Com signal go to a high level. At time t₈ after that, the Com signal goes to a low level, while the Trans1 signal goes to a high level. Further, at time t₉ after that, the Reset signal and the Trans1 signal go to a low level.

In the duration from time t₇ to time t₈ where the Reset signal and the Com signal are at a high level, the electric charge accumulated in both of the first capacitance section C₁ and the second capacitance section C₂ of each pixel section P_(m,n) is outputted from the transistor T₅ to the wiring L_(2,n), and then inputted to the second signal processing section 30, so that the second voltage value V_(2,m,n) corresponding to the electric charge amount is outputted from the second signal processing section 30.

In the duration from time t₈ to time t₉ where the Reset signal and the Trans1 signal are high, the electric charge generated by the photodiode PD of each pixel section P_(m,n) is outputted from the transistor T₅ to the wiring L_(2,n) via a route not passing through the first capacitance section C₁ and the second capacitance section C₂, and then inputted to the second signal processing section 30, so that the third voltage value V_(3,m,n), corresponding to the electric charge amount is outputted from the second signal processing section 30. At that time, the feedback capacitance section of each integration circuit 31 _(n) of the second signal processing section 30 may be set at each capacitance value sequentially so that the third voltage value V_(3,m,n) may be outputted for each capacitance value.

Further, at that time, in each integration circuit 31 _(n), the reference voltage V_(ref1) (for example, 1.5V) is inputted to the non-inverting input terminal of the amplifier A₃₁, as a result of the operation of the switch SW₃₁₄. As such, when a comparatively low reference voltage V_(ref2) is inputted to the non-inverting input terminal of the amplifier A₃₁, the dynamic range can be enhanced in the photodetection.

Then, after time t₉, in the data output section 40, for each of the N pixel sections P_(m,1)-P_(m,N) of the m-th row, any one of the voltage values consisting of the first voltage value V_(1,m,n), the second voltage value V_(2,m,n), and the third voltage value V_(3,m,n) is selected by the selecting section 41 so that the voltage value is converted into a digital value by the A/D conversion section 42. Further, depending on which of the three voltage values has been selected, the bit of the digital value is shifted by the bit shift section 43 by a necessary number of bits, so that the digital value D_(m,n) is outputted.

As such, when the processing is completed for each of the N pixel sections P_(m,1)-P_(m,N) of the m-th row, processing is performed on each of the N pixel sections P_(m+1,1)-P_(m+1,N) of the next (m+1)-th row. Here, in the duration after time t₉ where the processing is performed in the data output section 40 on each of the N pixel sections P_(m,1)-P_(m,N) of the m-th row, processing corresponding to the above-mentioned processing performed from time t₁ to time t₉ may be performed on each of the N pixel sections P_(m+1,1)-P_(m+1,N) of the next (m+1)-th row.

The invention is not limited to the above-mentioned embodiment, and hence various modifications are possible. In the above-mentioned embodiment, one voltage hold section H_(n) per M pixel sections P_(1,n)-P_(M,n) of each column has been provided in the first signal processing section 20. However, one voltage hold section per each pixel section P_(m,n) may be provided in the first signal processing section 20. In the latter case, the first voltage value V_(1,m,n) corresponding to the incident light intensity on each pixel section P_(m,n) in the same duration can be held by the voltage hold section corresponding to the pixel section P_(m,n).

Further, in the above-mentioned embodiment, one set of an integration circuit 31 _(n), a CDS circuit 32 _(n), and a hold circuit 33 _(n) per M pixel sections P_(1,n)-P_(M,n) of each column has been provided in the second signal processing section 30. However, one set of the integration circuit, the CDS circuit, and the hold circuit per each pixel section P_(m,n) may be provided in the second signal processing section 30. In the latter case, the second voltage value V_(2,m,n) corresponding to the incident light intensity on each pixel section P_(m,n) in the same duration can be held by the hold circuit corresponding to the pixel section P_(m,n). The same situation holds for the third signal processing section.

A photodetection apparatus according to the invention is applicable to a solid state image pickup device used in an imaging device, a photometry device, a distance measuring device, or the like.

As described above, with the photocathode of the present invention, there can be accomplished an improvement in productivity thereof and an improvement in the detection sensitivity of an electron tube employing the same.

From the invention thus described, it will be obvious that the invention may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended for inclusion within the scope of the following claims. 

1. A photodetection apparatus comprising: a pixel section comprising a photodiode for generating electric charge of an amount corresponding to incident light intensity, a first capacitance section for accumulating the electric charge generated by the photodiode, a second capacitance section having a larger charge accumulation capacitance than the first capacitance section and accumulating the electric charge generated by the photodiode, first transfer means comprising a first transistor that is coupled between the photodiode and the first capacitance section for transferring the electric charge generated by the photodiode to the first capacitance section, second transfer means comprising a second transistor that is coupled between the photodiode and the second capacitance section for transferring the electric charge generated by the photodiode to the second capacitance section, an amplification transistor having a gate terminal which is connected to the first capacitance section and which outputs a voltage value corresponding to the amount of electric charge accumulated in the first capacitance section, first output means for selectively outputting the voltage value outputted from the amplification transistor, second output means for selectively outputting the electric charge accumulated in each of the first capacitance section and the second capacitance section, and initializing means for initializing the electric charge of each of the first capacitance section and the second capacitance section to an initialization state; a first signal processing section having a voltage hold section for receiving the voltage value outputted by the first output means of the pixel section, at least one voltage follower circuit that receives the voltage value output by the voltage hold section, and a subtraction circuit that receives the voltage value output by the at least one voltage follower circuit and outputs a first voltage value corresponding to the voltage value; and a second signal processing section having an integration circuit for receiving the electric charge amount outputted by the second output means of the pixel section, a correlated double sampling circuit that receives a voltage value output by the integration circuit, and a hold circuit that receives a voltage value output by the correlated double sampling circuit and outputs a second voltage value corresponding to the electric charge amount.
 2. A photodetection apparatus according to claim 1, wherein the pixel section further comprises third output means for selectively outputting the electric charge generated by the photodiode via a route not passing through the first capacitance section and the second capacitance section, and the apparatus further comprises a third signal processing section for reading the electric charge amount outputted by the third output means of the pixel section and outputting a third voltage value corresponding to the electric charge amount.
 3. A photodetection apparatus according to claim 2, wherein the second signal processing section includes the third signal processing section.
 4. A photodetection apparatus according to claim 1, wherein the second signal processing section comprises: an amplifier having a first input terminal, a second input terminal, and an output terminal, the first input terminal receiving the electric charge amount outputted by the second output means of the pixel section while the second input terminal receives a reference voltage; and a feedback capacitance section connected between the first input terminal and the output terminal of the amplifier, such that the electric charge amount outputted by the second output means of the pixel section is accumulated in the feedback capacitance section, so that a second voltage value corresponding to the amount of accumulated charge is outputted.
 5. A photodetection apparatus according to claim 4, wherein the first input terminal of the amplifier of the second signal processing section is connected via a common terminal to the second output means and the initializing means of the pixel section, and a value of the reference voltage inputted to the second input terminal of the amplifier of the second signal processing section is variable.
 6. A photodetection apparatus according to claim 4, wherein the feedback capacitance section comprises a plurality of capacitance elements having different capacitance values, and a plurality of switches which are each coupled to a respective capacitance element and are controlled to switch between open and closed states to selectably connect the capacitance elements between an input and output of the feedback capacitance section, thus changing the capacitance of the feedback capacitance section based on the open and closed states of the switches.
 7. A photodetection apparatus according to claim 1, further comprising a selecting section for receiving the first voltage value outputted from the first signal processing section and the second voltage value outputted from the second signal processing section and selecting and outputting any one of these voltage values consisting of the first voltage value and the second voltage value.
 8. A photodetection apparatus according to claim 2, further comprising a selecting section for receiving the first voltage value outputted from the first signal processing section, the second voltage value outputted from the second signal processing section, and the third voltage value outputted from the third signal processing section, and selecting and outputting any one of these voltage values consisting of the first voltage value, the second voltage value, and the third voltage value.
 9. A photodetection apparatus according to claim 7 or 8, further comprising an A/D conversion section for receiving the voltage value outputted from the selecting section, performing A/D conversion on the voltage value received, and then outputting a digital value corresponding to the voltage value on which the A/D conversion has been performed.
 10. A photodetection apparatus according to claim 9, further comprising a bit shift section for receiving the digital value outputted from the A/D conversion section, shifting the bit of the digital value depending on which value has been selected in the selecting section, and then outputting the value.
 11. A photodetection apparatus according to claim 1, wherein the first signal processing section is connected to the first output means.
 12. A photodetection apparatus according to claim 11, wherein the first output means comprises a transistor and the first signal processing section is connected to the transistor to receive the voltage value outputted from the transistor.
 13. A photodetection apparatus according to claim 1, wherein the second signal processing section is connected to the second output means.
 14. A photodetection apparatus according to claim 13, wherein the second output means comprises a transistor and the second signal processing section is connected to the transistor to receive the electric charge outputted from the transistor. 